The present invention relates to a fuel injector suitable for controlling the delivery of two different fuels into an internal combustion engine. In particular, but not exclusively, the invention relates to a fuel injector suitable for injecting a gaseous fuel and a liquid fuel.
Internal combustion engines for heavy-duty and industrial applications are typically fuelled by diesel. However, the use of natural gas as an alternative to diesel is of increasing interest. Natural gas is relatively abundant and relatively cheap, and can, in principle, provide similar levels of power to diesel whilst producing lower particulate and nitrogen oxide (NOx) emissions.
Natural gas can be used in place of diesel to fuel a compression-ignition engine, in which combustion of the fuel occurs as a result of compression of the air-fuel mixture in the cylinder. However, because natural gas has a higher auto-ignition temperature than diesel, it can be necessary to initiate combustion with a pilot injection of diesel fuel before introducing the natural gas to the combustion chamber.
In one type of natural gas-powered engine, known as a high-pressure direct injection (HPDI) engine, both natural gas and diesel are injected directly into the combustion chamber. Due to the space constraints in an engine cylinder head, it is desirable to inject both fuels using one fuel injector per cylinder. This requires a fuel injector that is specially adapted to keep the two fuels separate within the injector, and to deliver independently the respective fuel at the appropriate time.
One such ‘dual fuel’ injector is described in International Patent Application Publication No. WO 00/15956. In this example, a fuel injector with a concentric twin nozzle arrangement is provided. Inner and outer valve needles are engageable at their lower ends with respective valve seats to control the flow of fuel through respective inner and outer sets of outlets. The outer valve needle controls the injection of natural gas through the outer set of outlets, and the inner valve needle controls the injection of diesel through the inner set of outlets. The outer valve needle is tubular to accommodate the inner valve needle, and the inner set of outlets is formed at a tip of the outer valve needle.
The inner and outer valve needles are controlled independently by two electromagnetic control valves, which are configured to control the pressure of a control fluid (normally diesel fuel) within respective control chambers for the inner and outer valve needles. Each control chamber is connected to a source of control fluid at relatively high pressure. Each control valve is operable to connect the respective control chamber to a low-pressure drain for the control fluid. In this way, opening of each control valve causes a reduction in the pressure of the control fluid in the corresponding control chamber, resulting in opening of the corresponding valve needle.
It is a challenge to accommodate the various injector components within an acceptable housing due to space limitations under the engine cover, particularly in a dual fuel injector where two actuators are required to provide the actuation means for the two valve needles.
It is with a view to addressing this problem that the present invention provides an improved fuel injector which is suitable for use in injecting two different fuel types.
Against that background, from a first aspect, the present invention resides in a fuel injector for an internal combustion engine, the injector comprising a first actuator for controlling movement of a first valve needle for injecting a first fuel into a cylinder of the engine, and a second actuator for controlling movement of a second valve needle for injecting a second fuel into the cylinder. Each of the actuators is axially spaced along a longitudinal axis of the injector body and comprises a respective conductive element for carrying current to the actuator. The injector further comprises an electrical connector module including first and second electrical connector means for connection with an associated one of the conductive elements for the actuators, and wherein the electrical connector module is mounted between the first and second actuators along the longitudinal axis of the injector body.
Preferably, the injector further comprises a first control valve assembly and a second control valve assembly, wherein the first actuator is operable to control the first control valve assembly and the second actuator is operable to control the second control valve assembly.
The first control valve assembly may be operable to control fuel pressure within a first control chamber associated with the first valve needle, thereby to control movement of the first valve needle, and wherein the second control valve assembly is operable to control fuel pressure within a second control chamber associated with the second valve needle, thereby to control movement of the second valve needle.
In one embodiment, the first and second control valve assemblies are housed within opposed ends of the injector body.
By way of example, the electrical connector module may project, at least in part, from a side of the injector body.
One benefit of the invention is that the electrical connector module may be mounted to the side of the injector body, to project laterally from the injector body, so that the overall height of the injector assembly is reduced compared to arrangements having a top-mounted connector. In addition, as both the first and second actuators share a common, integrated electrical connector module, the complexity and part-count is reduced.
The first and second actuators are electromagnetic actuators comprising a solenoid coil or winding, although other types of actuators may also be used.
In one embodiment, the electrical connector module includes a body portion, for example a barrel, which extends laterally from the injector body, and an insertion portion which is received within a chamber of the injector body to make electrical connection with the first and second conductive elements for the actuators.
The first and second conductive elements for the actuators may be housed, at least partially, within an elongate stem. The elongate stem of each of the first and second actuators may have its longitudinal axis offset laterally from the longitudinal axis of the injector body.
Each of the first and second electrical connector means may include a respective first or second pair of connector pins which extend axially through the electrical connector module for connection with the conductive element associated with the associated one of the first and second actuators.
The conductive elements may include an electrically conductive blade which includes a portion that is biased outwardly from the associated stem. The outward biasing of the blade portion ensures that a good electrical connection is made with the connector pins when they engage with the blades.
In one embodiment, the first and second pairs of connector pins are of different length, with the connector pins of one pair being of the same length, so that the shorter connector pins make contact with the conductive element spaced laterally closer to a module side of the injector body and the longer pins make contact with the conductive element spaced laterally further away from the module side. This is a particularly convenient arrangement to ensure that both the first and second actuators can be connected to a common electrical connector module.
The insertion portion may include first and second legs which are spaced apart so as to flank the electrical connector pins.
The insertion portion is provided with means for preventing incorrect insertion of the electrical connector module into the chamber.
For example, the insertion portion may be provided with a slot of relatively short length and a slot of relatively long length so that the actuator stem that is spaced laterally closer to a module side of the injector body can be accommodated within the slot of relatively long length.
It is helpful to ensure that incorrect assembly of the injector and the electrical connector module is not possible, and the feature of the slots is beneficial in this regard as it prevents the electrical connector module being inserted into the injector body the wrong way round.
The invention will now be described, by way of example only, with reference to the following figures in which:
Referring to
A tip region 18 of the nozzle body 14 includes an outer set of outlets (not shown) and an inner outlet (also not shown). Injection of a first fuel through the outer set of outlets is controlled by a first or outer valve needle, and injection of a second fuel through the inner outlet is controlled by a second or inner valve needle. The inner and outer valve needles are not shown in the accompanying Figures but are housed within the nozzle body 14, with the inner needle being in concentric arrangement with, and internal to, the outer valve needle. The inner and outer valve needles are coaxial with the central injector axis A-A. Each of the inner and outer sets may include a single outlet, or a plurality of outlets. The injector may be configured to inject diesel fuel through the inner outlet(s) and natural gas through the outer outlet(s), or vice versa.
Movement of the inner and outer valve needles is controlled by means of first and second control valve assemblies, 20, 22 respectively, which control fuel pressure in first and second control chambers (not shown) associated with the inner and outer valve needles, respectively, in a manner which would be familiar to a person skilled in the art.
As shown most clearly in
The first control valve assembly 20 and the second control valve assembly 22 are both electromagnetically actuated by means of a respective electromagnetic actuator. Each actuator has its own respective core (not shown) formed of a generally tubular pole piece and an electromagnetic solenoid coil or winding. A first solenoid coil of the first actuator is disposed around a pole piece of the first actuator, and a second solenoid coil of the second actuator is disposed around a pole piece of the second actuator. Further detail of the construction and operation of the actuators would be familiar to a person skilled in the art as is described, for example, in the Applicant's granted patent EP0740068B.
Each actuator is housed within the main injector body 12, together with the first and second control valves assemblies, 20, 22 respectively. The first control valve assembly and the first actuator are situated in an upper region of the injector body 12 and the second control valve assembly and the second actuator are situated in a lower region of the injector body 12. The first and second control valve assemblies, and their associated actuators, are therefore housed at opposed ends of the injector body 12.
The first control valve assembly includes a first control valve member that is slidably received in a bore in the upper region of the injector body 12. The first control valve member is attached to a first armature that is movable in response to the electromagnetic field generated as a result of current being applied to the first solenoid coil. In a similar fashion, the second control valve assembly includes a second control valve member that is slidably received in a bore in the lower region of the injector body. The second control valve member is attached to a second armature that is movable in response to the electromagnetic field generated as a result of current being applied to the second solenoid coil.
As can be seen most clearly in
The first stem 26 of the first control valve assembly extends downwardly within the upper region of the injector body 12 and projects into a connector chamber 30 formed part way along the length of the injector body 12. The first stem 26 is eccentric to, and radially displaced from, the axis of the first control valve member, and hence to the first solenoid coil, and is eccentric to, and radially displaced from, the central axis A-A of the injector body 12.
The second stem 28 of the second control valve assembly extends upwardly within the lower region of the injector body 12 and also projects into the connector chamber 30. The second stem 28 is eccentric to, and displaced radially from, the axis of the second control valve member, and hence to the second solenoid coil, and is also eccentric to, and radially displaced from, the central axis A-A of the injector body 12.
Referring also to
On each stem 26, 28, a first blade includes a portion that is biased outwardly to project laterally from a first side of the stem, whilst a second blade includes a portion that is biased outwardly to project laterally from a second side of the stem. The pair of blades associated with each stem is arranged to connect with an electrical connector module of the injector, referred to generally as 40. The electrical connector module connects with an external power supply (not shown) for the engine, to allow current to be supplied to the solenoids of the actuators, via the blades, as will be described in further detail below.
The first and second control valve assemblies 20, 22 are identical to one another, but with one having its stem offset to one side of the injector axis A-A and the other having its stem offset to the other side of the injector axis A-A.
The first control valve member is biased into a first position, known as a filling position, by a first biasing spring (not shown). When the first solenoid coil is energised, the associated armature is caused to move such that the first control valve member is drawn into a second position, known as a drain position. Similarly, the second control valve is biased into a first position, known as a filling position, by a second biasing spring. When the second coil is energised, the armature of the second control valve member is caused to move so as to draw the second control valve member into a second position, known as a drain position.
By controlling the first and second control valve members to move between their filling and drain positions, fuel pressure within control chambers associated with the inner and outer valve needles is controlled. In this way opening and closing movement of the inner and outer valve needles can be controlled to control the injection of the first and second fuels into the combustion chamber in accordance with a chosen injection strategy.
Referring in more detail to
The electrical connector module 40 includes a connector body in the form of a hollow body portion or barrel 42 which is of generally square external cross section having an external width, W1, as best seen in
The electrical connector module 40 further includes an insertion portion 54 for receipt within the connector chamber 30 of the injector. The insertion portion 54 includes first and second opposed legs 56, 58 which extend from the support 44 at the base of the barrel 42, on the other side of the support from the barrel. Each of the legs 56, 58 includes a flat central portion flanked on each side by a curved portion. For the first leg 56, the flat portion is indicated by reference numeral 56a and the curved portions on either side are indicated by reference numerals 56b, 56c. Each of the first and second legs is shaped for receipt within the connector chamber 30 of the injector body 12 so that, with the legs 56, 58 received within the connector chamber 30, the barrel of the electrical connector module projects laterally from the injector body 12. The connector module defines a central connector axis B-B which, when the module is mounted to the injector body 12, extends perpendicularly to the central injector axis A-A, as indicated in
The width of the barrel, W1, is greater than the spacing between the first and second legs 56, 58 so that the module has a stepped outer profile. The separation between the first and second legs is defined by width, W2.
The module is of moulded construction so that the barrel 40, the support 44 and the legs 56, 58 are all formed as an integrated part which supports electrical connector means of the module, comprising four electrical connectors pins 60, 62, 64, 66.
The pins 60, 62 of the first pair are arranged horizontally next to one another, spaced apart with one on each side of the central axis B-B of the module 40. In a similar fashion, the pins 64, 66 of the second pair are arranged horizontally next to one another, spaced apart, with one on each side of the central axis B-B of the module 40. The pins 60, 62 of the first pair lie vertically above the pins 64, 66 of the second pair so that the spacing between each pin and each of its neighbouring, adjacent pins is substantially identically. The pins 60, 62 of the first pair have a shorter length than the pins 64, 66 of the second pair.
When the electrical connector module 40 is inserted into the connector chamber 30, each of the short pins 60, 62 engages with an associated one of the blades of the downwardly extending stem 26. In a similar fashion, each of the long pins 64, 66 engages with an associated one of the blades of the upwardly extending stem 28. The outward biasing of the blades ensures that a good electrical connection is made between each pin/blade pair.
As can be seen most clearly in
In use, movement of the inner and outer valve needles is controlled hydraulically by varying the pressure of control fluid or fuel in the associated control chambers. When the first control valve assembly 20 is actuated, the first control valve member is in its drain position and fuel pressure within the control chamber is relatively low. The inner valve needle is therefore lifted away from its seating to allow injection of the first fuel through the associated outlets. When the first control valve assembly 20 is de-actuated by removing or reducing the current applied to the solenoid via the electrical connector module 40, the first control valve member is moved into its filling position, increasing fuel pressure within the associated control chamber and seating the valve needle to terminate injection of the first fuel.
The second control valve assembly is operated in the same way by varying the current that is applied to the second actuator via the electrical connector module 40 so as to control injection of the second fuel.
By arranging the first and second control valve assemblies so that they share a common or integrated electrical connector module 40, the accommodation space required for the injector installation is reduced compared to an arrangement in which separate electrical connectors are required for each control valve assembly. In addition, as the electrical connector module 40 is arranged to extend laterally from the injector housing 12, as opposed to a top-mounted connector, the height of the complete injector assembly is reduced so that it can more easily be accommodated in the space beneath the engine cover.
A further benefit of the electrical connector module is that the contact between the electrical pins 60, 62, 64, 66 and the electrically conductive blades of the stems is secure and does not involve convoluted paths for connecting wires through the injector body 12.
Further modifications and variations not explicitly described above can also be contemplated without departing from the scope of the invention as defined in the appended claims.
Number | Date | Country | Kind |
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1309126.9 | May 2013 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/058650 | 4/29/2014 | WO | 00 |